（1）掺入纤维可以改善SCC的高温性能以及高温爆裂现象， 不同类型纤维的作用效果不同。
（2）钢纤维在基体中形成相互交错的纤维网络从而产生桥接作用，并利用自身良好的导热性改善温度应力带来的损伤，但单掺钢纤维仅能提高混凝土的抗拉性能，降低爆裂程度，并不能提高混凝土的抗爆裂性能。
（3）PP纤维在高温下熔化，形成了排气孔道，有利于导热和蒸汽排出，降低内压，减轻温度梯度引起的应力作用，从而抑制了高温爆裂现象。
（4）混掺PP纤维与钢纤维可以同时改善高温下混凝土的渗透性和抗裂性，提高混凝土的抗爆裂性能。
（5）掺入纤维能够提升高温下SCC的残余抗压强度、弯曲性能和断裂能，且单掺钢纤维或混掺钢纤维+PP纤维的提升效果优于单掺PP纤维和玻璃纤维。掺入纤维后，混凝土梁在弯曲作用下的裂缝条数增加、平均间距减小，弯曲性能和延性得到改善。
（6）高温模拟试验与实际火灾情况存在偏差，实际火灾时，升温过程是不规律、不均匀的，且环境复杂，这给构件承载力和蒸汽压力预测带来了困难。因此，有必要开发出更加简便、通用的数值模拟方法，以便对火灾作用下纤维增强SCC的力学性能进行模拟研究。此外，虽然混杂纤维混凝土在高温下有较好的表现，但纤维的种类、混杂方式、混杂比例等还有待深入研究。

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